In-process vision detection of flaw and FOD characteristics

ABSTRACT

An inspection system ( 9 ) includes an idler wheel ( 61 ) that is coupled to a fabrication system ( 8 ) and is in contact with a backing layer ( 65 ) of an applied material ( 64 ), A rotation sensor ( 63 ) monitors the idler wheel ( 61 ) and generates a rotational signal. A controller ( 24 ) is coupled to the rotation sensor ( 63 ) and determines a characteristic of one or more flaws and FOD ( 19 ) on a composite structure ( 12 ) in response to the rotation signal.

RELATED APPLICATIONS

This application is a divisional of, and claims priority from, prior application Ser. No. 10/904,727, filed Nov. 24, 2004 now U.S. Pat. No. 7,424,902. Other related applications include U.S. patent application Ser. Nos. 09/819,922; 10/846,974; and 10/904,719.

BACKGROUND INFORMATION

1. Technical Field

The present invention relates generally to the fabrication of composite structures and to material placement machines. More particularly, the present invention relates to systems and methods of detecting flaws and foreign object debris (FOD) and characteristics thereof during the fabrication of a composite structure.

2. Background of the Invention

Composite structures have been known in the art for many years. Although composite structures can be formed in many different manners, one advantageous technique for forming composite structures is a fiber placement or automated collation process. According to conventional automated collation techniques, one or more ribbons of composite material, known as composite strands or tows, are laid down on a substrate. The substrate may be a tool or mandrel, but more conventionally, is formed of one or more underlying layers of composite material that have been previously laid down and compacted.

Conventional fiber placement processes in the formation of a part utilize a heat source to assist in the compaction of the plies of composite material at a localized nip point. In particular, the ribbons or tows of the composite material and the underlying substrate are heated at the nip point to increase resin tack while being subjected to compressive forces to ensure adhesion to the substrate. To complete the part, additional strips of composite material can be applied in a side-by-side manner to each layer and can be subjected to localized heat and pressure during the consolidation process.

Unfortunately, defects can occur during the placement of the composite strips onto the underlying composite structure. Such defects can include tow gaps, overlaps, dropped tows, puckers, and twists. Additionally, foreign objects and debris (FOD), such as resin balls and fuzz balls, can accumulate on a surface of the composite structure. Resin balls are small pieces of neat resin that build up on the surfaces of the fiber placement head as the pre-impregnated tows pass through the guides and cutters. The resin balls become dislodged due to the motion and vibration of the fiber placement machine, and drop on to the surface of the ply. Subsequent courses of applied layers cover the resin ball and a resultant bump is created in the laminate whereat there may be no compaction of the tows. The fuzz balls are formed when fibers at the edges of the tows fray and break off as the tows are passed through the cutter assembly. The broken fibers collect in small clumps that fall onto the laminate and are covered by a subsequent layer.

Composite structures fabricated by automated material placement methods typically have specific maximum allowable size requirements for each flaw, with these requirements being established by the production program. Production programs also typically set well-defined accept/reject criteria for maximum allowable cumulative defect width-per-unit-area.

Composite laminates fabricated by fiber placement processes are typically subjected to a 100% ply-by-ply visual inspection for both defects and FOD. Typically, these inspections are performed manually during which time the fiber placement machine is stopped and the process of laying materials halted until the inspection and subsequent repairs, if any, are completed. In the meantime, the fabrication process has been disadvantageously slowed by the manual inspection process and machine downtime associated therewith.

Current inspection systems are capable of identifying defects in a composite structure during the fabrication process without requiring machine stoppage for manual inspections. The inspection systems are capable of detecting, measuring, marking, and identifying FOD “in-process” or during the fabrication of a composite structure. This, in turn, eliminates the need for manual FOD inspections and the machine downtime associated therewith.

It is desirable that an inspection system be capable of determining characteristics of flaws and FOD, including size, location, type, density-per-unit area, and cumulative defect width-per-unit area. Thus, there exists a need for an improved inspection system and method of detecting, identifying, and determining characteristics of flaws and FOD within and during the fabrication of a composite structure.

SUMMARY OF THE INVENTION

One embodiment of the present invention provides an inspection system that includes an idler wheel. The idler wheel is coupled to a fabrication system and is in contact with a backing layer of an applied material. A rotation sensor monitors the idler wheel and generates a rotational signal. A controller is coupled to the rotation sensor and determines a characteristic of one or more flaws and FOD on a composite structure in response to the rotation signal.

The embodiments of the present invention provide several advantages. One such advantage is the provision of a composite structure in-process fabrication inspection technique that accurately determines flaw and FOD characteristics.

Another advantage provided by an embodiment of the present invention, is the provision of a composite structure in-process fabrication inspection technique that accurately determines flaw and FOD characteristics without actually communicating with a material placement machine to obtain location coordinates.

Yet another advantage provided by an embodiment of the present invention, is the provision of a composite structure in-process fabrication inspection technique that determines the density of flaws and FOD per unit area and the width of the flaws and FOD per unit area.

Furthermore, another embodiment of the present invention identifies areas of a composite structure for further analysis in view of processing parameters, such as placement speed and programmed gap information, and flaw and FOD trends. In analyzing processing parameters and flaw and FOD trends one can adjust fabrication processes to prevent future flaw and FOD occurrences.

Moreover, the present invention allows for the in-process repair of a composite structure upon detection of a flaw or FOD.

The present invention itself, together with further objects and attendant advantages, will be best understood by reference to the following detailed description, taken in conjunction with the accompanying drawing.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side schematic view of a fabrication system incorporating a flaw and FOD inspection system in accordance with an embodiment of the present invention;

FIG. 2 is a block diagrammatic and perspective view of the position detection system and components of a material placement machine in accordance with an embodiment of the present invention;

FIG. 3 is a perspective view of an application portion of a fabrication system incorporating a flaw and FOD inspection system in accordance with another embodiment of the present invention;

FIG. 4 is a perspective view of light sources according to the embodiment of FIG. 2;

FIG. 5 is a perspective view of a fabrication system incorporating a flaw and FOD inspection system in accordance with another embodiment of the present invention;

FIG. 6 is a logic flow diagram illustrating a method of determining flaw and FOD characteristics during the fabrication of a composite structure in accordance with an embodiment of the present invention;

FIG. 7 is a ply layout illustrating course and frame locations in accordance with an embodiment of the present invention;

FIG. 8 is a top view of a sample irregularly shaped ply in accordance with an embodiment of the present invention;

FIG. 9 is a front view of a display and user controls illustrating the detection of flaws and FOD and indication of flaws and FOD characteristics in accordance with an embodiment of the present invention; and

FIG. 10 is a logic flow diagram illustrating a method of fabricating a composite structure in accordance with an embodiment of the present invention.

DETAILED DESCRIPTION

In each of the following Figures, the same reference numerals are used to refer to the same components. While the present invention is described with respect to systems and methods of detecting flaws and foreign object debris (FOD) and characteristics thereof during the fabrication of a composite structure, the present invention may be adapted for various applications and systems, such as fabrication of structures and components, production line applications, or other applications and systems known in the art. The present invention may be applied to both the fabrication of aeronautical and non-aeronautical systems and components.

In the following description, various operating parameters and components are described for one constructed embodiment. These specific parameters and components are included as examples and are not meant to be limiting.

Also, in the following description the term “foreign object debris (FOD)” refers to any resin ball, fuzz ball, impurity, backing paper, backing film, or other foreign or undesirable object contained within or on a composite structure. FOD may refer to one or more of the stated objects.

In addition, the term “flaw” refers to any defect within a composite structure or structure under fabrication. A flaw may refer to a tow gap, an overlap of material, a dropped tow, a pucker, a twist or any other flaw known in the art.

Referring now to FIG. 1, a side schematic view of a fabrication system 8 is shown incorporating a flaw and FOD detection and inspection system 9 in accordance with an embodiment of the present invention. The fabrication system 8 includes a lamination system 10, as best seen in FIGS. 2 and 3, that may utilize an automated collation process to form a composite structure 12, as shown. The inspection system 9 is positioned proximate the composite structure 12 and includes one or more illumination devices or light sources 13 (only one is shown) and one or more detectors 14 (only one is shown). The light sources 13 generate light arrays 16 that are directed at a portion 18 of the composite structure 12 to reveal flaws and FOD 19 within that portion 18. The inspection system 9 also includes a flaw and FOD position detection system 20, which determines the position of the flaws and FOD 19. A controller 24 is coupled to the detectors 14 and the position detection system 20 and interprets data received therefrom. The collected data may be used to adjust the operation of the fabrication system 8, the inspection system 9, and the lamination system 10, and to indicate, detect, and allow for the correction of the flaws and FOD 19. The controller 24 may store the received data and/or related information in the memory or storage device 26. System parameters and operation may be adjusted via the user interface 28.

During the fabrication of the composite structure 12, the composite structure 12 may be formed of adjacent tows or strips of composite tape (not shown) to form layers 29. The strips include multiple fibers that are embedded in a resin or other material, which becomes tacky or flowable upon the application of heat. The strips are arranged on a work surface 30 of a table, mandrel, or tool 32, and compacted with a compaction roller to form the composite structure 12. A compaction roller 34 can be seen in FIG. 2. The automated collation process includes guiding the composite strips from material creels (not shown) to an automated collation or fiber placement machine, such as a machine made by Cincinnati Milacron and Ingersoll Milling Machines. In particular, the composite strips are guided to a head unit or assembly 36, which may be best seen in FIG. 3, and fed under the compaction roller 34. Focused heat energy is then applied to adhere the incoming material and the underlying previously laid material. With the combination of pressure and heat, the composite strips are consolidated into a previous applied layer to form an additional layer on the composite structure 12.

An example of an automated collation technique that may be used is described in U.S. Pat. No. 6,799,519 B2, entitled “Composite Material Collation Machine and Associated Method for High Rate Collation of Composite Materials.” The contents of U.S. Pat. No. 6,799,519 B2 are incorporated herein by reference.

Referring now to the inspection system 9, the light sources 13 are positioned to emit light arrays at the selected portion 18 of the composite structure 12. The light sources may be positioned at various angles as known in the art, depending on the application. Any number of light sources may be utilized even though a specific number is shown.

The light sources 13 are positioned relative to the composite structure 12 via a mounting apparatus 40. The mounting apparatus 40 includes a main shaft 42, a secondary shaft 44, and a locking clamp 46 for adjusting the position of the light sources 13. The mounting apparatus 40, in turn, can be attached to the frame 48, to the detectors 14, to the bracket 50, or to some other object that defines a common position for both the light sources 13 and the detectors 14 to maintain a constant spatial relationship relative to one another.

The light sources 13 may be selected from an infrared light or another type of light having an infrared component, such as a halogen light source or other incandescent light sources. In other embodiments, the light sources 13 are in the form of a fluorescent light source (e.g., white light LEDs, a low pressure/mercury filled phosphor glass tube, etc.), a strobe or stroboscopic light source, a noble gas arc lamp (e.g., xenon arc, etc.), a metal arc lamp (e.g., metal halide, etc.), or a laser (e.g., pulsed laser, solid state laser diode array, infrared diode laser array, etc.). The light from the light sources 13 may pass through optical fibers to the point of delivery, an example of which is shown in FIG. 5. The light sources 13 may include LEDs arranged in an array or cluster formation. In one specific embodiment, the light sources 13 include twenty-four LEDs mounted in an array upon a three-inch square printed circuit board.

In some embodiments, the light sources 13 are operated at a power level that increases the infrared (IR) component of the light arrays, which aids in the inspection of dark tow material, such as carbon. In this regard, exemplary power levels in the range of approximately one hundred fifty watts (150 W) and in the wavelength range of about seven hundred nanometers to one thousand nanometers (700 nm-1000 nm) may be used. However, the particular power levels and wavelengths for the light sources 13 depends at least in part on the speed and sensitivity of the detectors 14, the speed at which the material is being laid, the light delivery losses, and the reflectivity of the material being inspected.

The detectors 14 may be of various types and styles. A wide range of detectors may be used including commercially available cameras capable of acquiring black and white images. In one embodiment, the detectors 14 are in the form of a television or other type of video camera having an image sensor (not shown) and a lens 13 through which light passes when the cameras are in operation. Other types of cameras or image sensors can also be used, such as an infrared-sensitive camera, a visible light camera with infrared-pass filtration, a fiber optic camera, a coaxial camera, a charge coupled device (CCD), or a complementary metal oxide sensor (CMOS). The detectors 14 may be positioned proximate the composite structure 12 on a stand (not shown) or mounted to the frame 48 or a similar device. In embodiments of the present invention that do not include a reflective surface, the detectors 14 may be positioned approximately six inches from the top surface 52 of the composite structure 12, and mounted to the frame 48 by way of the bracket 50 and associated connectors 54. Also, any number of detectors may be utilized.

The controller 24 may be microprocessor based such as a computer having a central processing unit, memory (RAM and/or ROM), and associated input and output buses.

The controller 24 may be a portion of a central main control unit, be divided into multiple controllers, or be a single stand-alone controller as shown.

The connectors 54 may be rivets, screws, or the like and used to mount the detectors 14 to the frame 48 in a stationary position. Alternatively, the connectors 54 may be a hinge-type connector that permits the light sources 13, the detectors 14, and associated assembly to be rotated away from the composite structure 12. This embodiment is advantageous in situations when there is a desire to access parts of the material placement device that are located behind the detectors 14 and associated assembly, such as during maintenance, cleaning, or the like.

The inspection system 9 may also include filters 56 (only one is shown), which may be utilized in conjunction with the lens 58 for filtering the light passing therethrough. In one embodiment, the filters 56 are designed to filter the light such that the infrared component of or a certain infrared wavelength or range of wavelengths of the light is able to pass into the detectors 14. Thus, the filters 56 may prevent ambient visible light from entering the detectors 14 and altering the appearance of the captured image.

Other methods of filtering light can also be used to achieve the same, or at least used to provide a similar result. For example, the detectors 14 may be designed to include a built-in filter of equivalent optical characteristics. In addition, the filter 56 may be located between the lens 58 and the detectors 14. Alternatively, the detectors 14 may include image sensors that are sensitive in the infrared spectrum (i.e., an infrared-sensitive camera), thus eliminating the need for the filters 56.

The inspection system 9 may also include a marking device 60 for marking the location of the defects and the FOD on the composite structure 12. The marking device 60 may be attached to the frame 48 and be triggered by the controller 24 or similar device when a flaw or FOD is detected. The marking device 60 may deposit ink, paint, or the like onto the composite structure 12 in areas where flaws and FOD have been detected. The markings on the composite structure 12 enable the location of the flaws and FOD to be subsequently and readily identified either automatically or manually. The marking device 60 may also be adapted to mark flaws with different colored ink than that used to mark FOD. Alternatively, other marking or indicating methods can also be used, such as markings utilizing a pump-fed felt-tip marker or a spring-loaded marking pen, indications via audio or visual alerts, and the like.

Referring now also to FIG. 2, a block diagrammatic and perspective view of the position detection system 20 and components of a material placement machine are shown in accordance with an embodiment of the present invention. The position detection system 20 includes a material collection device 61, an idler wheel 62, and an idler wheel rotation sensor 63. The composite material 64 having a backing layer 65 is directed around the compaction roller 34 and adhered to the composite structure 12. As the composite material 64 reaches the compaction roller 34 it is heated and adhered to the composite structure 12. As the composite material 64 adheres to the composite structure 12 the backing layer 65 is pulled from the composite material 64, rolled around the compaction roller 34, around the return roller 66, over the idler wheel 62, and into the material collection device 61. The backing layer 65 may be in the form of a backing paper, as shown, or may be in some other form known in the art. The compaction roller 34 and the return roller 66 are part of a material placement machine or lamination system 10, the entirety of which is not shown. The lamination system 10 may be separate from the inspection system 9 and the position detection system 20.

The material collection device 61 may be in the form of a collection retainer, as shown, may be in the form of a material collection wheel, a take-up reel, a combination thereof, or may be in some other form known in the art.

The idler wheel 62 rests against the backing layer 65 and rotates as the backing layer 65 passes thereon. Motion of the backing layer 65 indicates that placement of the composite material 64 is in progress. The idler wheel 62 is free to rotate and may apply little to no pressure on the backing layer 65. The idler wheel 62 is coupled to the lamination system 15 and is suspended via an idler arm 67. The idler arm 67 may be position adjustable and pressure adjustable relative to the backing layer 65. The idler wheel may be keyed, such that the controller 24 may capture an image of the composite material 64 as it is applied for a predetermined number of idler wheel revolutions.

The rotation sensor 63 is proximate the idler wheel 62 and is coupled to the idler arm 67. The rotation sensor 63 monitors the rotation of the idler wheel 62 and generates a rotation signal indicative thereof. The rotation sensor may be in the form of an encoder, an infrared sensor, a rotary potentiometer, or other sensor known in the art that is capable of detection rotative position and velocity of the idler wheel 62.

The position detection system 20 may also include a collection roller 68 and a second rotation sensor or collection sensor 69. The collection roller is coupled to the collection device 61. The backing layer 65 is passed over the collection roller and into the collection device 61. The second rotation sensor 69 is proximate the collection roller 68 and detects the rotational position and velocity of the collection roller 68.

Although a return roller 66 is shown, this is intended as one possible example. A material placement machine may include a moveable compaction roller or a stationary show, as known in the art.

Referring now to FIGS. 3 and 4, a perspective view of an application portion of a fabrication system 8 incorporating a flaw and FOD inspection system 9′ and a perspective view of light sources 13′ are shown in accordance with another embodiment of the present invention. The inspection system 9′ includes two light sources 13′ (only one is shown) positioned relative to the composite structure 12 and the compaction roller 34 on either side of a reflective surface 70 and a detector 14′. FIG. 3 illustrates an alternative embodiment of the hinge-type connector 54 that mounts the light sources 13′, the detector 14′, the reflective surface 70, and associated head assembly 36 to the frame 48 by way of the bracket 50.

The light sources 13 and 13′ and the detectors 14 and 14′, of FIGS. 1 and 3, may be translated or moved relative to a composite structure, such as the composite structure 12. The adjustability and moveability of the light sources 13 and 13′ and detectors 14 and 14 provides flexibility in the capture of images of a composite structure. Sample systems including moveable cameras and light sources are described in detail in previously referred to U.S. patent application Ser. No. 10/217,805.

Although the light sources 13′ are shown in the form of four halogen light bulbs 74, other quantities, types, and styles of illumination sources may be utilized. A light reflection element 76 is located near the light sources 13′. The reflection element 76 includes a series of light reflecting surfaces 78 that redirect the light towards the desired area to be illuminated. This levels the illumination across the top surface of a composite structure and eliminates, or at least substantially reduces, the areas of intense light (i.e., hotspots) created by the brightest portion of the light source. Hotspots can lead to errors during the processing of images. The light reflection elements 78 are particularly advantageous for illuminating the curved/contoured surfaces of the composite structures because the redirection of the light permits a larger portion of a composite structure to be evenly illuminated.

The reflection element 76 is curved around the light sources 13′, such as in a parabolic shape. The reflection elements 78 are in the form of curved steps that are substantially parallel to the light source 13′. The distance between and the curvature of the reflection elements 78 may be selected for sufficient and even illumination generated from the sum of the two light sources 13′. This enables more consistent illumination of the composite structure 12, which prevents, or at least reduces, the image-processing errors due to inconsistent illumination of the composite structure 12. Alternatively, the shape and/or surface configuration of the reflection elements 78 may be modified using other techniques known in the art to produce consistent illumination and scattering of light.

In an exemplary embodiment, seventeen reflection elements are utilized and have an overall parabolic shape and a range of widths from about 0.125 inches at the outer edge of the reflection elements to about 0.250 inches at the center of the reflection elements. The reflection elements also have a uniform step height of about 0.116 inches. In other embodiments, however, the reflection elements 78 may be provided with different numbers of steps having different uniform or varying widths and different uniform or varying step heights.

Furthermore, the reflection elements 78 may be adjusted in order to direct the light produced by the light sources 13′ and scattered by the reflection elements 78 toward the selected portion of a composite structure. For example, as shown in FIG. 4, the reflection elements 78 are mounted to the mounting apparatus 40 with fasteners 80. The fasteners 80, when loose, are capable of being slid within slots 82 to correspondingly adjust the angle of the reflection elements 78 relative to a composite structure. Once the reflection elements 78 are positioned appropriately, the fasteners 80 are tightened to secure the reflection elements 78 in the desired position. Adjustments of the reflection elements 78 can also be enabled by other methods, such as by electronic means that permit remote adjustment of the reflection elements 78.

The detectors 14 are positioned near the composite structure 12 and when in the form of cameras are positioned to capture images of the selected illuminated portion, which is typically immediately downstream of the nip point at which a composite tow is joined with the underlying structure.

The light sources 13, the detectors 14, the reflective surface 16, and any reflection elements 78, may be mounted on the head unit 23 to allow for continuous capture of real-time data of the composite structure 12. The real time data may be captured as the head unit 36 is transitioned across the composite structure 12 and as the composite strips are laid down or applied.

The bracket 50 may be fastened to the hinge type connector 54 via a suitable fastener, such as a thumbscrew or any other fastener that may be utilized and inserted through hole 72 and then tightened to secure the assembly in place for operation. The fastener may be loosened or removed, for example, to rotate the light source and detector assembly away from the compaction roller 34 and other parts of the fabrication system.

The reflective surface 70 may be positioned near the composite structure 12, and angled such that the reflective surface 70 reflects an image of the illuminated portion to the detectors 14. In one embodiment, the angle of the reflective surface 70 to the composite structure is about sixty-five degrees, but the reflective surface 16 can also be positioned at any appropriate angle in order to reflect images of the illuminated portion to the detectors 14. The detectors 14 may be positioned to point toward the reflective surface 70 in order to capture the close-range images of the illuminated portion from the reflective surface 70. More than one reflective surface 70 may also be utilized in further embodiments of the present invention in which the reflective surface 70 cooperate in order to direct the images of the illuminated portion to the detectors 14.

The reflective surface 70 may be in various positions relative to a selected portion, such as portion 18. Reflective surface 70 can also be utilized to allow the detectors 14 to be placed in an advantageous positions, which might otherwise be blocked by portions of the compaction roller 34 and/or other parts of the fabrication system.

The configuration illustrated in FIG. 3 aids in the capturing of images of curved/contoured surfaces of a composite structure since the reflective surface 70 is positioned close to the composite structure. In addition, this configuration permits the detectors 14 to be positioned away from a composite structure, to prevent interference between the detectors 14 and components of the fabrication system 8′. Further, the reflective surface 70 can also provide a “square on” view of the selected portion being inspected, which, in turn, can improve the ability to dimension the two gaps for pass/fail decisions.

Referring now to FIG. 5, a perspective view of a fabrication system 8″ incorporating a flaw and FOD inspection system 9″ in accordance with another embodiment of the present invention is shown. The inspection system 9″ includes lights sources (not shown) that are at a remote location. The light sources generate light rays, which are passed through linear optical fiber arrays or fiber optic cable 90 to point of transmission 92 via light emitting heads 94. Light arrays are emitted from the fiber optic cable 90 toward the selected portion 18′ of the composite structure 12′ to detect flaws and FOD 19′. The use of fiber optic cables simplifies the number of components mounted on the head assembly.

Referring now to FIGS. 6 and 7, a logic flow diagram illustrating a method of determining flaw and FOD characteristics during the fabrication of a composite structure and a ply layout illustrating course and frame locations are shown in accordance with an embodiment of the present invention.

In step 95, strips of the composite material 64 are applied to the tool 32 to form the composite structure 12.

In step 96, as the strips are applied, the backing layer 65 is removed from the composite material 64 in turn causing the idler wheel 62 to rotate.

In step 97, the rotation sensors 63 and 69 generate the rotation signals that are indicative of the rotational position and velocity of the idler wheel 62 and the collection roller 68. The rotational signals are also indicative of any cessation in the backing layer, such as when the lamination system 10 or the application position of the composite material 64 is laterally transitioned to form another column or course. Cessation of motion indicates that material lay-down for the current course has stopped and that a new course may be started. The rotational signals may be compared, averaged, and utilized to accurately determine position of the lamination system 10. The rotational signals may also be utilized to determine when the backing layer is “bunching up” or not passing through the fabrication system appropriately.

FIG. 7 illustrates a sample single ply 98 of a rectangular composite structure 99 with frame rows 100 and courses 101. Seven rows of sixteen courses are shown. Of course, any number of rows and courses may be created. Also each ply, such as ply 98, may be of various shape, another example of which is shown in FIG. 8. The ply 98 is divided into multiple unit areas 102, each of which corresponding to an image frame. Each unit area 102 may have a width w greater than the width of the strips (not shown) of the composite material being applied and a height h that corresponds to a determined number of revolutions of the idler wheel 62. In one embodiment, the unit area width w is approximately equal to seven inches, the width of the composite material plus a half of an inch for each side of the material. In another embodiment, the height h is approximately seven inches corresponding to the circumference of the idler wheel 62. The frame numbers may be sequentially assigned even when the course number changes.

In step 104, the portion 18 of concern is selected. The portion 18 may include the entire composite structure under formation or may include a discrete segment or area of the composite structure. In step 105, the light sources 13 are activated to illuminate the selected portion 18. The light rays 16, which may be in the form of arrays, are generated such that both the flaws and FOD 19 may be detected simultaneously within the selected portion 18. The light sources may be activated throughout the material placement process.

In step 106, detectors, such as detectors 14 and 14′, monitor the portion 18 and generate status signals in response to the reflection of the light rays 16 off of the portion 18. The status signals contain information regarding the existence of flaws and FOD in the portion 18. The detectors 14 and 14′ detect light reflection characteristics of the flaws and FOD.

In step 107, the controller 24 determines one or more flaw and FOD characteristics in response to the rotation signal and the division of the current ply. The characteristics may be determined during the application of the composite material 64. The flaw and FOD characteristics may include size, location, position, type, density-per-unit area, cumulative defect width-per-unit area, and any other flaw and FOD characteristic known in the art. Width information of flaws and FOD provides gap and density information. Manufacturing specifications that govern automated material placement have acceptance requirements for various types of defects. For gaps there is a maximum allowable width for a single gap and a maximum allowable total width for of all of the gaps existing within a defined area. Likewise, for FOD there is a maximum allowable number of occurrences with a defined area. Thus, the detector 14 and/or the controller 24 may track the area that has been inspected and the number and total width of flaws that have been detected.

For example, the controller may determine longitudinal and lateral position of a flaw or FOD in response to the number of frames captured in a given row and the number of detected cessations per ply. The detector 14 or the controller 24 may store an image after a preset number of revolutions of the idler wheel 62. The number of revolutions remains constant and establishes the image frame height. This along with the constant width of the material course being placed establishes a constant rectangle, referred to as a frame. The frames are tracked by assigning a discrete number to each frame.

In step 107 A, the controller 24 generates an image count for each of the flaws and FOD to determine a linear distance to each of the flaws and FOD. The image count provides a course measurement of longitudinal position. In step 107 B, the controller 24 generates a revolution count indicative of the revolutions of the idler wheel 62, which is indicative of the position of the lamination system and any detected flaws and FOD in that position. The revolution count provides a fine measurement of longitudinal position within an image frame. In step 107 C, the controller 24 generates a cessation count for each of the flaws and FOD. In step 107 D, the controller 24 may also generate an applied layer or ply count indicative of the number of currently applied plies. In step 107 E, the controller 24 determines the position of the flaws and FOD in response to the image count, the revolution count, the cessation count, and the ply count.

In step 107 F, the controller 24 determines the flaw areal density. In step 107 F 1, the controller 24 counts the flaws and FOD in a current frame to generate a current flaw and FOD frame count. In step 107 F 2, the controller 24 sums the current flaw and FOD frame count with flaws and FOD of two adjacent frames of a previous course to generate a resultant sum. In step 107 F 3, the controller 24 determines flaw areal density for the portion in response to the resultant sum. The flaw areal density is equal to the resultant sum divided by the area of the portion.

In step 107 G, the controller 24 determines size of the flaws and FOD. In step 107 H, the controller 24 determines cumulative gap width per unit area in response to the portion 18, the frame, or a current set of frames and the size.

In step 108, the detected flaws and FOD 19 as well as the related characteristics thereof are indicated to a user via a display, such as that shown with respect to FIG. 9.

In step 109, the flaw and FOD characteristics as detected may be stored in an archival error file within the memory 26, such as in an error file. The characteristics may include the ply, course, and frame number associated with each flaw and FOD. Also, after a preset number of revolutions the detectors 14 or the controller 24 may store images of the portion 18 within the memory 26. Since the frame size is constant it is possible to establish the location of a defect on the surface by counting frames from an initial starting point. The detector 14, the controller 24, or other device that has access to the stored information may determine approximate location of each flaw and FOD therefrom separate from and without being hard-wired to the fabrication system 8 and/or the material placement machine, stated with respect to FIG. 2.

Referring now to FIG. 8, a top view of a sample irregularly shaped ply 110 is shown. The length of the courses 111 vary over the ply 110 and thus the image frames, corresponding to unit areas 112, are staggered. When a course ends in an angular cut, the last frame in that course may be assumed to be fully rectangular in shape for the purpose of designating a unit area. Flaw and FOD characteristics may be determined in response to the frame stagger. In the example embodiment, the unit areas 112 and thus the frames are in a 50% stagger. Each unit area is bordered by half portions of two adjacent unit areas. The unit areas and the frames may be oriented at any staggered percentage.

When determining flaw areal density, the number of flaws in any affected frame (diagonally cut frame) is summed with those in two adjacent frames of a previous course instead of one. Cumulative gap width is determined by measurement across a designated area in a direction perpendicular to the direction of material placement on a tool. For summation purposes the gaps may be assumed or assigned to extend an entire length of the affected image frames, such that location within a frame of gap location is unnecessary.

Positions of the flaws and FOD may be determined utilizing information from archived positions and engineering disposition and may be resolved utilizing known in-process flaw and FOD marking techniques.

Referring now to FIG. 9, a front view of a user display screen 120 and user controls 122 illustrating the detection of flaws and FOD 124 and indication of flaws and FOD characteristics in accordance with an embodiment of the present invention is shown. Although the operation and use of the display 120 is primarily described with respect to the embodiment of FIG. 1, it may be easily modified for and applied to other embodiments of the present invention. The user interface 28 includes the display 120, such as that on a computer monitor, and can also include an input device, such as a keyboard and mouse (not shown), for permitting an operator to move a cursor about the display 120 and input various system settings and parameters. The display 120 may be touch-sensitive for permitting the operator to input the desired settings by manually touching regions of the display screen.

The interface 28 includes an image window 126 in which an image 128, of the composite structure 12, is displayed for viewing by an operator or other user. The image 128 may be in the form of an unprocessed or processed camera image. When processed the image 128 or a portion thereof may be binarized. During binarization, all shades of gray above a predetermined threshold value may be changed to white, while all gray shades below the threshold value may be changed to black to heighten the contrast of defects and improve the accuracy of defect detection. As an alternative or in addition to binarization, rates of light level change in the raw image and color changes in the images may be used to identify the defects and FOD.

The interface 28 also includes a position window 129, which may display the ply number, course number, and frame number of the lamination system in a current state as is related to a currently viewed image.

The controls 122 allow for various user inputs to the system. The controls 122 may be used to adjust the binarization threshold. Generally, the setting of the binarization threshold involves a tradeoff between the sensitivity with which defects are detected and the resolution with which the defects are depicted. In one embodiment, the binarization threshold is set to about 128, which corresponds to the mid-point on the 8-bit digitizing range of 0 to 255. However, other binarization threshold values may be employed depending at least in part on the particular application, available lighting, camera settings, and other factors known in the art.

The controls 122 also allow the user to adjust or shift the viewing area within the window 126. During operation, the window 126 displays real-time moving video images of the illuminated portion of the composite structure 12 as the detectors 14 and/or the reflective surface 18 are moved relative to the composite structure 12. The controls 122 may be such to allow the user to input the maximum allowable dimensional parameters, the acceptable tolerances, as well as other known parameters for the flaws and FOD.

In addition to displaying images of the composite structure 12, the display screen 80 may also include a defect table 128, which lists the discovered flaws and FOD and provides related information thereof, such as location, size, and the like. The display 120 can further include status indicators 130 that notify the user whether a particular image area is acceptable or not acceptable based on predefined criteria, such as the maximum allowable dimensional parameters and tolerances.

Referring now to FIG. 10, a logic flow diagram illustrating a method of fabricating a composite structure in accordance with an embodiment of the present invention is shown. Although the logic flow diagram of FIG. 10 is primarily described with respect to the embodiment of FIG. 1, it may be easily modified to apply to other embodiments of the present invention.

In step 150, the fabrication system 8 applies the strips to form the layers 29 on the substrate 32 to form the composite structure 12. In step 152, the inspection system 9 illuminates selected areas of or the entire composite structure 12 during the application of the strips to detect the flaws and FOD 19 as described above with respect to the method of FIG. 5. Flaws and FOD may be detected continuously throughout the material placement process and continuously over selected portions or the entire composite structure 12.

In step 154, the inspection system 9 distinguishes, identifies, and determines characteristics of the flaws and FOD 19 and the location thereof and generates a composite structure defect signal. Examples regarding systems and methods for identifying defects in a composite structure during fabrication thereof are included in U.S. patent application Ser. No. 09/819,922, filed on Mar. 28, 2001, entitled “System and Method for Identifying Defects in a Composite Structure” and in U.S. patent application Ser. No. 10/217,805, filed on Aug. 13, 2002, entitled “System for Identifying Defects in a Composite Structure”. The contents of U.S. patent application Ser. Nos. 09/819,922 and 10/217,805 are incorporated herein by reference as if fully set forth herein.

In step 156, the fabrication system 8 may in response to the composite structure defect signal alter the operation thereof. The fabrication system 8 may cease further application of the strips until one or more portions of the composite structure 12 are repaired, may alter the manner in which the strips are applied, may adjust parameters of the fabrication system 8 or inspection system 9, or may perform other tasks known in the art.

At any time upon or after the generation of the status signals and/or the defect signals the controller 24 may store data or images in the storage device 26 for future or off-line analysis and/or processing. Future analysis may be based on processing parameters, such as material placement speed and programmed gap information, and flaw and FOD trends.

The above-described steps in the methods of FIGS. 5 and 8, are meant to be illustrative examples, the steps may be performed synchronously, continuously, or in a different order depending upon the application.

The present invention provides systems and methods for the simultaneous detection of flaws and FOD using a single illumination level. The present invention simplifies the detection of the flaws and FOD and allows for efficient identification and repair thereof.

While the invention has been described in connection with one or more embodiments, it is to be understood that the specific mechanisms and techniques which have been described are merely illustrative of the principles of the invention, numerous modifications may be made to the methods and apparatus described without departing from the spirit and scope of the invention as defined by the appended claims. 

1. A fabrication system comprising: a lamination system comprising a layer applicator applying a plurality of composite material layers to a substrate to form a structure; and a flaw and foreign object debris (FOD) inspection system proximate said lamination system comprising; an idler wheel coupled to said lamination system and contacting a backing layer of an applied material; a rotation sensor monitoring said idler wheel and generating a rotational signal; a detector detecting at least one flaw and FOD and generating a flaw and FOD detection signal; and a controller coupled to said rotation sensor and determining at least one characteristic of said at least one flaw and FOD on said structure in response to said rotation signal and said flaw and FOD signal.
 2. A fabrication system as in claim 1 wherein said controller alters operation of the fabrication system in response to said at least one characteristic.
 3. A fabrication system comprising: a lamination system comprising a layer applicator applying a plurality of composite material layers to a substrate to form a structure; and a flaw and foreign object debris (FOD) inspection system proximate said lamination system comprising; at least one illumination device illuminating a portion of the structure; at least one detector monitoring said portion and detecting at least one flaw and FOD in said portion during application of said plurality of composite material layers in response to reflection of said light rays off of said portion and generating a flaw and FOD detection signal; an idler wheel coupled to said lamination system and contacting a backing layer of an applied material; a rotation sensor monitoring said idler wheel and generating a rotational signal; and a controller coupled to said rotation sensor and determining at least one characteristic of said at least one flaw and FOD in response to said rotation signal and said flaw and FOD detection signal.
 4. A fabrication system as in claim 3 wherein said controller alters operation of the fabrication system in response to said at least one characteristic. 